Ferrites: A ‘Spintronics’ perspective

‘Spin’ based electronics (spintronics) also known as magneto electronics has emerged as new field of interest in solid state device technology where the intrinsic spin of an electron, with which the magnetic moment is associated, instead of or in addition to the fundamental electronic charge of the same is exploited. Conventional electronic devices including today’s integrated circuits rely on the transport of electrical charge carriers -electrons - in a semiconductor such as silicon where in the information processing is performed using transistors that work by transfer of electrons, but the storage is done by magnetic recording using spin of electrons in a separate ferromagnetic metal. By the accomplishment of spintronics, tomorrow's technology can be seen magnetism (spin) and semi conductivity (charge) combined in one device that exploits both charge and spin to process and store the information. We may then be able to use the capability of mass storage and processing of information in the same device. Such a device will be called as “Spintronic device”. The potential advantages of spintronic devices will be higher speed, greater efficiency, and better stability, in addition to the low energy required to flip a spin. Some of the spintronic devices are spin value transistors, spin light emitting diodes, non volatile memory, logic gates, optical isolators, ultra flat optical switches etc.

Figure : The charge and spin associated with an electron

In general, such devices explore mostly the spin of electrons to encode and process data rather than the charge. The advantage of spin over charge is that spin can be easily manipulated by externally applied magnetic fields, a property already in use in magnetic storage technology. Another significant property of spin is its long coherence, or relaxation, time (nanoseconds, compared to tens of femto seconds during which electron momentum decays) once created it tends to stay that way for a long time, unlike charge states, which are easily destroyed by scattering or collision with defects, impurities or recombination. These characteristics open the possibility of developing devices that could be much smaller, consume less power and will be more powerful for certain types of computations which is not possible with electron-charge-based systems. We know that electrons are spin ½ fermions and therefore constitute a two- state system with spin up and spin down. To make a spintronic device, the primary requirements are, first a system that can generate a current of spin – polarized electrons comprising more of one spin spices-up or down than the other (called a spin injector), and secondly, a separate system sensitive to the spin polarization of the electrons (spin detector). There are metal based spintronic devices in which spin–polarized current is generated by passing current through magnetic material; the most common application based on this effect is a giant magnetoresistance (GMR) device. Another one is semiconductor based spintronic devices, which is of the greatest relevance.

 Figure: The two interstitial sites in ferrites

The current interest in spintronics is focused on (a) the search for new materials in which spin polarization of injected currents could be increased and (b) the identification of highly polarized materials aiming for increasing tunnel magnetoresistance. Based on their potential applications in spintronics, ZnO-based materials have received renewed interest. On the other hand, ferrites with spinel structure are known for their applications in high frequency devices, and are also promising candidate for spintronics because their magnetic properties could be engineered as a function of size. Among ferrites, magnetite (Fe₃O₄) has high Curie temperature, weak crystalline anisotropy, and high degree of spin polarization, which makes it a potential candidate for spin electronics devices. The spinel structure consists of two cation sites for metal cation occupancy, i.e. tetrahedral (A) and octahedral (B) sites, where metal ions are coordinated by oxygen. If ‘A’ sites are occupied by divalent metal cation and ‘B’ sites are occupied by trivalent Fe, the structure of ferrites is said to be normal spinel. The structure is known as inverse spinel when ‘A’ sites are completely occupied by Fe³⁺ cation whereas ‘B’ sites are randomly occupied by divalent cation and Fe³⁺. Based on the first principle calculations it has been suggested that ZnFe₂O₄ is small band gap insulator and MnFe₂O₄ is a low carrier density half-metal in fully ordered state could be a candidate for spintronics. Recent studies on Zn_1-xCo_xFe₂O₄ show its potential application for magnetoelectric devices in multilayer structure. Ferrite-based structures could be useful for spintronics applications, if they exhibit half-metallicity with small carrier concentration. In this perspective, our interest in studies related to the synthesis and characterization of such mixed spinel structures and their polymer coated nanocomposites is having obvious importance towards achieving an optimal device composition for spintronics.

About eco-friendly magnetic refrigeration- The Future

One of the difficulties with conventional vapour-compression refrigeration cycles is that most of the better refrigerants are ozone depleting substances consisting of chlorinated fluorocarbons (HCFCs) like freon gas. 'Freon' is a trade name for a family of  haloalkane refrigerant manufactured by DoPont and other companies. These refrigerants are commonly used due to their superior stability and safety properties: they are not flammable nor obviously toxic as are the fluids they replaced, such as Sulphur dioxide. Unfortunately, these chlorine-bearing refrigerants reach the upper atmosphere when they escape. In the stratosphere, CFCs break up due to UV-radiation, releasing their chlorine atoms. These chlorine atoms act as catalyst in the breakdown of ozone, thus causing severe damage to the ozone layer that shields the Earth's surface from the Sun's strong UV radiation. The chlorine will remain active as a catalyst until and unless it binds with another particle, forming a stable molecule. So the major risk involved with this refrigerator is that the manufacturers have to be careful with not to let the harmful freon gas leak out. Newer refrigerants, currently being the subject of research, have reduced ozone depletion effect that include HCFCs (R-22, used in most homes today) and HFCs (R-134a, used in most cars) and have replaced most CFC use. HCFCs in turn are being phased out under the Montreal Protocol and replaced by hydrofluorocarbons (HFCs), such as R-410A, which lack chlorine. However, CFCs, HCFCs, and HFCs all have large global warming potential. Supercritical carbon dioxide, known as R-744 have similar efficiencies compared to existing CFC and HFC based compounds, and have many orders of magnitude lower global warming potential . Although modern refrigerators have replaced freon with a less harmful liquid, other environmental cooling techniques are being actively explored. One novel possibility is to use magnets to extract heat away, where rather than going into the expansion of a gas—as in conventional refrigerators—the thermal energy goes into disordering the aligned spins of a magnet. Magnetic refrigeration has three prominent advantages compared with compressor-based refrigeration. First, there are no harmful gases involved; second, it may be built more compactly as the working material is a solid; and third, magnetic refrigerators generate much less noise.

    Magnetic refrigeration utilizes the magnetocaloric effect (MCE). This effect causes a temperature change when a certain metal is exposed to a magnetic field. All transition metals and lanthanide series elements obey this effect. These metals, known as ferromagnets, tend to heat up as a magnetic field is applied. As the magnetic field is applied, the magnetic moments of the atom align. When the field is removed, the ferromagnets cool down as the magnetic moments become randomly oriented. A magnetic field can easily align the spins on the manganese sites so that if the magnetized material is allowed to come into thermal contact with a ‘hot’ object, then heat can depolarize the spins as per the scheme suggested in the flow chart. Soft ferromagnets are the most efficient and have very low heat loss due to heating and cooling processes. Gadolinium, a rare-earth metal, exhibits one of the largest known magnetocaloric effects. Also one can employ arc-melted alloys of gadolinium, silicon, and germanium that provide greater temperature ranges at room temperatures in the design of most modern magnetic refrigeration system.

The flowchart of magnetic refrigeration; Here, H is the magnetic field, Q is the heat transfer, T is the temperature and ΔT_ad is the temperature change when the spins depolarize (with no heat transfer).

   Keeping this principle in mind, hypothetically one can design a magnetic refrigerator as follows: The heat transfer fluid for the magnetic refrigeration system may be a liquid alcohol-water mixture having a given freezing point, assuring the mixture does not freeze at the set operating temperatures. This heat transfer fluid shall be cheaper than traditional refrigerants and also eliminates the environmental damage produced from these refrigerants. During the operation the heat transfer fluid gets cooled to desired lower level of temperature by the non-magnetized cold set of beds that contain the small spheres of magnetocaloric material. This cooled fluid is then sent to the cold heat exchanger where it absorbs the excess heat from the freezer. This fluid leaves the freezer at 0°F. The warm fluid then flows through the opposite magnetized set of beds, where it is heated up to the desired higher level. This hot stream is then cooled by room temperature air in the hot heat exchanger. The cycle then repeats itself after the beds have switched positions back and forth to the field while still keeping them in contact with the heat transfer plates. Thus there will have an eco-friendly, non-compressor, noise free and highly compatible refrigeration system for house hold and automobile cooling applications. In this perspective, our group is engaged in developing such an eco-friendly solid state system based on superpapramagnetic nanoferrites especially for applications at near room temperature magnetic refrigeration.

Teaching Philosophy

Teaching physics at any level needs strategic planning before a defined aim could be achieved for the Mass. The information path should be crystal clear and the shortest possible to reach the final goal. It is important to show, how a number of basic facts build up a deeper understanding of the subject and thus knowledge. A teacher should have refined by self from a good teacher to a teacher in need out of the ocean of experiences  earned wherein teaching and research should not be contrary to each other.

Teaching interests include Solid state Physics, Spectroscopy, Electrodynamics, Quantum Mechanics, Engineering Physics.

Current Research Interests and Future Plans

Study of the overall magnetic behaviour of nano-crystalline spinel ferrites having different particle sizes and synthesis, characterization and magnetic behaviour of conducting polymer encapsulated magnetic nanoparticles. The temperature and field dependent dc magnetization measurements, Mössbauer spectroscopic measurements, dielectric and conductivity measurements and Optical energy band analysis have been performed. XRD, FTIR, AFM, positron annihilation studies have been performed for thorough understanding of the material characteristics. Current interest is on the development of low T_c rare earth metal substituted ferrites with biocompatible encapsulation for the combined application of self controlled hyperthermia and drug delivery. Fabrication of single domain magnetic nanoparticles of size less than 10 nm and having high value magnetocrystalline anisotropy constant is of another interest. Also recently started work on some nanocrystalline magnetic oxide materials exhibiting near room temperature refrigeration characteristics using magneto caloric effect (MCE) for accomplishing eco-friendly solid state refrigerarant.

My future concerns in research are to explore ways and means to put into practical use the technology we developed to convert these nanostructured materials into biomedical field and highly advanced data storage density of state-of-the-art hard disk drive systems applications. Since the nanoparticles could be highly tailor made and convert in to processable material it carries immense potential to use in various magneto-optic devices also. These aspects I would like to study in the event of me getting an opportunity to research and teaching.

Skills

      Synthesis techniques like chemical co-precipitation technique, sol-gel technique, in-situ polymerization, electrochemical polymerization, plasma polymerization, spin coating etc.

    Material Characterization techniques like XRD, VSM, Mössbauer spectroscopy, UV optical spectroscopy, AFM, FT-IR., Impedance Spectroscopy, cyclic voltametry, dc resistivity and Positron annihilation Spectroscopy.

    Radiation dose measurements techniques like GM-tube based environmental gamma dose survey meter, SSNTD based twin-cup radon thoron dosimeter, thermo-luminescent detector based dosimeter, TL-card badge reader.

    Computer knowledge includes latest Microsoft Ms office soft wares, Adobe PageMaker, Origin, d-base, NORMOS fitting program, Win TLD (Specially designed software from Bhabha Atomic Research Centre, Mumbai), Map source (a GPS software)  etc.

 

Visits to National Institutes

1.      MANIPAL University, Uduppi- for attending 55^th DAE-SSP during Dec. 2010

2.      BANASTHALI Women’ University, Jaipur, Rajasthan during July 2010

3.      TIFR, Mumbai- for delivering an invited seminar talk on Rare earth substituted low T_c superparamagnetic nano-ferrites- on 13^th April 2010

4.      IUAC, New Delhi- for beam time- during March 2010; for workshop- during Sept. 2006

5.      IIT Bombay- for attending MR08- during  May 2008; lab visits- during Feb. 2006

6.      UGC DAE CSR Indore- for annual report presentation on behalf of UE & P lab NIT, Calicut- during Feb. 2010; for Mössbauer measurements- during Nov.- Dec. 2007

7.      UGC DAE CSR Kolkotta- for positron annihilation life time measurement- during  March 2007

8.      Saha Institute of Nuclear Physics, Kolkotta- for attending International conference on structure & dynamics: from macro to micro- during December 2006

9.      BARC Mumbai- for training as part of a research fellowship- during Feb. 2006; Sept. 2006; June 2008

10.  IISc, Bangalore, during  Feb. 2005

Memberships & Activities

1. Member of International NanoScience Community
2. Reviewer of many reputed international and national journals in Materials Science
3. Executive member, Centre for Advanced Scientific Research, Kollam, Kerala.
4. Honorary Research Fellow, Mössbauer and Magnetism Lab, University of Rajasthan, Jaipur, India.
5. Joint Secretary, National Conference on Thermo physical Properties (NCTP ‘07) held at Amrita Vishwa Vidyapeetham, Kollam, Kerala (2007).
6. Local coordinating committee member, National Conference on Organic electronics, held at S. N. College, Kollam, Kerala (2006)
7. Actively participated in Jyothirgamaya ’05 Conference at Sree Narayana College, Kollam, Kerala
8. Actively involved and monitored four M.Sc project works and one M.Phil dissertation work during the period of my Ph. D.
9. Actively involved in the case-control study of low level radiation area in the south west coast of Kerala and prepared a detailed report on it and submitted to BARC, Mumbai.
10. Resident Tutor, E-Hostel, NIT Calicut, Kerala during Nov. 2009 to April 2010
11. Execute member, Venpalakkara West Residence Association, Kollam Since 2002.

Experiences

Teaching Experiences:  

2012 October – Present: Assistant Professor of Physics, Sree Narayana College, Punalur,Kollam, Kerala (India)

                                                                                                   

2011 March – 2012 August: Assistant Professor of Physics, Arulmigu Meenakshi Amman College of Engineering, Vadamavandal (near Kanchipuram), Tamil Nadu (India)

2010 August – 2011 February: Assistant Professor of Physics, Jagannath University (Deemed), Chaksu, Jaipur, Rajasthan (India)

2010 May - 2010 July: Sr. Lecturer in Physics, SADTM Campus, Jaipur National University (Deemed), Jaipur, Rajasthan (India)

Research Experiences:

2009 Nov. - 2010 April: Research Assistant in BRNS sponsored research program at National Institute of Technology, Calicut, Kerala, India

2009 April- 2009 Oct.: Research Fellow, Mossbauer and Magnetism Lab., University of Rajasthan, Jaipur, Rajasthan (India)

2006 Feb. - 2009 March: Junior Research Fellow in BRNS sponsored research program at Condensed Matter Physics Laboratory, S. N. C., Kollam, Kerala, India

Technical:

2004 August ­­­- 2006 January: Trainee, School of Instrumentation and Information Technology (SIIT), Kottayam, Kerala, India